Gas and electric heating system

ABSTRACT

The gas and electric heating system has combination gas and electric heat generators to provide energy to a steam-generating boiler. The system has a blue-flame, gaseous-fuel burner disposed externally to provide heat to a steam-generating boiler and electrical heating elements that are positioned inside the boiler. Steam generated in the boiler flows to a heating core. The core is positioned in an air duct. Heat is transferred from the core to air flowing through the duct. The heated air flows from the duct into an area to be heated. Controls are provided to correlate the functions of the various components in the system.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention generally relates to heating systems. More specifically, the present invention is drawn to a gas and electric heating system having a boiler that utilizes both gaseous fuel and electric energy to generate steam.

2. Description of the Related Art

Potential shortages of gas and oil and pollution generated during hydrocarbon combustion have caused builders to consider electric energy as a cleaner alternative for heating steam-producing boilers. However, the high costs of producing electricity and the relative inefficiency of using only electric power to generate steam render this alternative economically imprudent. The heating industry and the consumer would certainly welcome a heating system that could incorporate the best features of both an electric and a hydrocarbon-fueled, steam-generated heating system. Thus, a gas and electric heating system solving the aforementioned problems is desired.

SUMMARY OF THE INVENTION

The gas and electric heating system is a high-efficiency heating system that employs combination gas and electric heat generators to provide energy to a boiler that generates steam. The system comprises a blue-flame, gaseous-fuel burner disposed externally to provide heat to a steam-generating boiler, and electrical heating elements that are positioned inside the boiler. Steam generated in the boiler flows to a heating core. The core is positioned in an air duct so that heat is transferred from the core to air flowing through the duct. The heated air flows from the duct into an area to be heated. Controls are provided to correlate the functions of the various components in the system. The duct can be oriented in any direction (horizontal, down-flow, up-flow, etc.).

Accordingly, the instant invention presents a heating system that employs a combination of energy sources to produce steam. The heating system is effective and efficient and may reduce the user's annual heating bill up to 80%. The system provides for an arrangement of improved elements for the purposes described that are inexpensive, dependable and fully effective in accomplishing their intended purposes.

These and other features of the present invention will become readily apparent upon further review of the following specification and drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagrammatic view of a gas and electric heating system according to the present invention.

FIG. 2 is a schematic drawing of the electrical control circuitry for a gas and electric heating system according to the present invention.

FIG. 3 is a partial, perspective view of the boiler tank for a gas and electric heating system according to the present invention.

Similar reference characters denote corresponding features consistently throughout the attached drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Attention is first directed to FIG. 1, wherein the gas and electric heating system is diagrammatically illustrated and is generally indicated at 10. System 10 comprises a blue-flame, gaseous-fuel, burner manifold assembly 12. Gaseous fuel is provided via conduit 14 to the manifold assembly 12. Primary and secondary combustion air is provided in a conventional manner in quantities to allow blue-flame combustion. A pilot burner 12 a is positioned adjacent manifold assembly 12 and functions to ignite the mixture of fuel and air to produce a flame indicated at 15. Valves 16 and 18 control the flow of gas to manifold assembly 12 and pilot burner 12 a. Flame 15 is directed to heat boiler tank 20 to generate steam therein. A flame shield 22 surrounds the space between manifold assembly 12 and boiler tank 20. Flame shield 22 functions to concentrate the heat to an area beneath the boiler tank 20 and to prevent extraneous air from entering the flame area, thereby allowing the flame to burn steadily.

Water is fed to boiler tank 20 via water conduit 24. Shutoff valve 26, low-water cutout valve and switch 28, and water-feeder sensor 30 control the flow of water through conduit 24. A drain valve 32 and pressure-relief valve 34 are disposed on boiler tank 20 for obvious safety reasons. Electric heating elements 36, 38 (shown in phantom lines) are positioned within the interior of boiler tank 20. Two elements are preferred. However, one element or more than two elements may be used, if suitable.

Energy applied to boiler tank 20 by flame 15 and electrical elements 36, 38 combine to generate steam. The generated steam flows from boiler tank 20 through conduit 40 and into heating core 42. Gauge 44 is positioned on conduit 40 to monitor the temperature and pressure of steam flow. Control 46 functions to regulate and monitor the pressure of the steam. Heating core 42 is positioned in the exit duct 50 a of blower 50. Blower-driven air is heated as it flows over core 42 and into space S (the space that is to be warmed by the heated air). A control sensor 52 is disposed at the exit of duct 50 a to monitor blower output and air temperature. A relatively small bleeder line 54 allows an amount of steam to pass from the core directly into space S for humidification purposes. A conventional thermostat 64 is disposed in space S to control system operation in the usual manner.

Circuitry for controlling operation of the system is illustrated in FIG. 2. The circuit includes a fuse 60 in series with an on/off switch 62. Parallel sub-circuit 63 comprises thermostat 64, pressure control 46, low water cutout switch 28 a, gas valve control 16, contactor 66 and transformer 66 a. Heating elements 36, 38, water feeder sensor 30 and blower motor 68 are in parallel. Switches 46 a and 52 a are responsive to pressure control 46 and control sensor 52 respectively.

As best seen in FIG. 3, boiler tank 20 is positioned adjacent burner manifold 12. The burner generates flames at approximately 300° Fahrenheit. The flame shield has been omitted for clarity. Tank 20 can be fabricated from any suitable metallic material (steel, alloys of steel, etc.). The tank 20 houses heating elements 36, 38 therein. The heating elements are each rated at 1,500 watts. Steam generated in tank 20 exits to the heat core via line 40. Steam condensed in the core is returned to the tank through conventional return lines.

It is to be understood that the present invention is not limited to the embodiment described above, but encompasses any and all embodiments within the scope of the following claims. 

1. A gas and electric heating system, comprising: a boiler tank forming a steam producing chamber; a burner manifold for generating a blue flame, the burner manifold being positioned adjacent to and spaced from the boiler tank; at least one electric heating element positioned in the steam producing chamber; and a first conduit connected to the boiler tank for supplying water to the steam producing chamber.
 2. The gas and electric heating system according to claim 1, further including a second conduit connected to said burner manifold for supplying gaseous fuel to said burner manifold.
 3. The gas and electric heating system according to claim 2, further including a third conduit connected to said boiler tank for conveying steam from said steam producing chamber.
 4. The gas and electric heating system according to claim 1, further including a flame shield encompassing the space between said burner manifold and said boiler tank.
 5. The gas and electric heating system according to claim 1, further including means on said first conduit for controlling the flow of water to said boiler tank.
 6. A gas and electric heating system, comprising: a boiler tank forming a steam producing chamber; a burner manifold for generating a blue flame, the burner manifold being positioned adjacent to and spaced from the boiler tank; a plurality of electric heating elements positioned in the steam producing chamber; a heating core connected to the steam producing chamber for receiving steam therefrom; an air blower having a duct, the heating core being positioned in the duct; a first conduit connected to the boiler tank for supplying water to the steam producing chamber; and means on said first conduit for controlling the flow of water to the boiler tank.
 7. The gas and electric heating system according to claim 6, further including: a second conduit connected to said burner manifold for supplying gaseous fuel to said burner manifold; and means on the second conduit for controlling the supply of gaseous fuel to said burner manifold.
 8. The gas and electric heating system according to claim 7, further including: a third conduit connecting said boiler tank to said heating core for supplying steam from said steam producing chamber to said heating core; and means on the third conduit for controlling the supply of steam from said steam producing chamber to said heating core.
 9. The gas and electric heating system according to claim 6, further including a flame shield encompassing the space between said burner manifold and said boiler tank.
 10. A gas and electric heating system, comprising: a boiler tank forming a steam producing chamber; a burner manifold for generating a blue flame, the burner manifold being positioned adjacent to and spaced from the boiler tank; a flame shield encompassing the space between the burner manifold and the boiler tank; a plurality of electric heating elements positioned in the steam producing chamber; a heating core connected to the steam producing chamber for receiving steam therefrom; an air blower having a duct for providing heated air into an area to be warmed by the heated air, the heating core being positioned in the duct; a first conduit connected to the boiler tank for supplying water to the steam producing chamber; and means on the first conduit for controlling the flow of water to the boiler tank.
 11. The gas and electric heating system according to claim 10, further including a small bleeder line connected to said heating core, the bleeder line opening into the area to be warmed for supplying humidifying steam to the area.
 12. The gas and electric heating system according to claim 10, further including: a second conduit connected to said burner manifold for supplying gaseous fuel to said burner manifold; and means on the second conduit for controlling the supply of gaseous fuel to said burner manifold.
 13. The gas and electric heating system according to claim 12, further including: a third conduit connecting said boiler tank to said heating core for supplying steam from said steam-producing chamber to said heating core; and means on the third conduit for controlling the supply of steam from said steam producing chamber to said heating core.
 14. The gas and electric heating system according to claim 10, further including a control sensor in said duct for controlling said blower.
 15. The gas and electric heating system according to claim 14, further including: a second conduit connected to said burner manifold for supplying gaseous fuel to said burner manifold; and means on the second conduit for controlling the supply of gaseous fuel to said burner manifold.
 16. The gas and electric heating system according to claim 15, further including: a third conduit connecting said boiler tank to said heating core for supplying steam from said steam producing chamber to said heating core; and means on the third conduit for controlling the supply of steam from said steam producing chamber to said heating core. 